Optical system for collecting distance information within a field

ABSTRACT

Optical systems and methods for collecting distance information are disclosed. An example optical system includes a first transmitting optic, a plurality of illumination sources, a pixel array comprising at least a first column of pixels and a second column of pixels, each pixel in the first column of pixels being offset from an adjacent pixel in the first column of pixels by a first pixel pitch, the second column of pixels being horizontally offset from the first column of pixels by the first pixel pitch, the second column of pixels being vertically offset from the first column of pixels by a first vertical pitch; and a set of input channels interposed between the first transmitting optic and the pixel array.

CROSS-REFERENCE TO RELATED PATENT APPLICATION

This application is a continuation of U.S. patent application Ser. No.15/685,384, filed Aug. 24, 2017, which claims the benefit of U.S.Provisional Patent Application No. 62/379,130, filed on Aug. 24, 2016,the disclosures of each of which are hereby incorporated by reference intheir entirety.

TECHNICAL FIELD

This invention relates generally to the field of optical sensors andmore specifically to a new and useful system optical system forcollecting distance information in the field of optical sensors.

BACKGROUND

Light detection and ranging (LiDAR) systems have been used in a widerange of applications, e.g., agriculture, forest planning andmanagement, environmental assessment, survey, mapping, imaging, andvehicle automation etc. Unlike cameras, LiDAR systems can be operated atnight and under any weather. Further, LiDAR systems are not affected bylow sun angles, and can provide distance contours directly based uponreturned lights from illuminated objects.

However, it remains a challenge to provide 2D or 3D distance informationwith higher precision, lower costs and faster results.

SUMMARY

Systems and methods in accordance with various examples of the presentdisclosure provide a solution to the above-mentioned problems. Anexample optical system for collecting distance information comprises afirst transmitting optic configured to collect illumination beams of aplurality of illumination sources reflected from a field outside theoptical system; a pixel array comprising at least a first column ofpixels and a second column of pixels, each pixel in the first column ofpixels being offset from an adjacent pixel in the first column of pixelsby a first pixel pitch, the second column of pixels being horizontallyoffset from the first column of pixels by the first pixel pitch, thesecond column of pixels being vertically offset from the first column ofpixels by a first vertical pitch; and a set of input channels interposedbetween the first transmitting optic and the pixel array, the set ofinput channels comprising at least a first plurality of input channelsand a second plurality of input channels, each of the first plurality ofinput channels configured to communicate one of the collectedillumination beams from the first transmitting optic to a correspondingpixel in the first column of pixels, each of the second plurality ofinput channels configured to communicate one of the collectedillumination beams from the first transmitting optic to a correspondingpixel in the second column of pixels.

In one aspect of the present disclosure, the first transmitting optichas a first focal length and defines a focal plane opposite the field.The set of input channels comprise an aperture layer disposedsubstantially coincident the focal plane, the aperture layer comprisinga set of apertures that comprises at least a first plurality ofapertures and a second plurality of apertures; a set of lens, the set oflens comprising at least a first plurality of lens and a secondplurality of lens, each of the first plurality of lens corresponding toone of the first plurality of apertures, each of the second plurality oflens corresponding to one of the second plurality of apertures; and anoptical filter disposed adjacent to the set of lens and opposite the setof apertures.

In another aspect of the present disclosure, each input channel in theset of input channels is coaxial with a corresponding pixel in the pixelarray such that the set of input channels is positioned in a skewed gridarray substantially similar to the pixel array.

In yet another aspect of the present disclosure, each input channel inthe set of input channels comprises a lens in the set of lens and acorresponding aperture in the set of apertures, the lens beingsubstantially aligned with the corresponding aperture.

In yet another aspect of the present disclosure, each of the set of lenshas a second focal length, and is configured to offset the focal planeopposite the first transmitting optic by the second focal length andcollimate light rays having wavelengths substantially equivalent to anoperating wavelength of the optical system.

In yet another aspect of the present disclosure, the optical systemfurther comprises a second transmitting optic. The plurality ofillumination sources is positioned along a focal plane of the secondtransmitting optic, each illumination beam projected by the secondtransmitting optic having substantially the same size and geometry as afield of view of a corresponding input channel in the set of inputchannels.

In yet another aspect of the present disclosure, the aperture layer isseparately fabricated by selectively metallizing a glass wafer andetching the set of apertures into metallized glass wafer.

In yet another aspect of the present disclosure, the pixel array isintegrated on a semiconductor wafer. The first transmitting optic andthe set of input channels are fabricated on the semiconductor waferusing at least one of photolithography technique or wafer-level bondtechnique.

In yet another aspect of the present disclosure, the fix pixel pitch isn times of the first vertical pitch, in which n is a positive integer.

In yet another aspect of the present disclosure, the optical systemfurther comprises an actuator configured to rotate the pixel array, theset of input channels and the first transmitting optic around a verticalaxis. The actuator comprises a rotary electric motor and an opticalencoder, the rotary electric motor configured to control a rotationalspeed of the pixel array, the set of input channels and the firsttransmitting optic based upon outputs of the optical encoder, theoptical encoder coupled to the pixel array via a closed-loop feedbackcircuit.

An example method of making an optical system for collecting distanceinformation comprises providing a first transmitting optic configured tocollect illumination beams of a plurality of illumination sourcesreflected from a field outside the optical system; providing a pixelarray that comprises at least a first column of pixels and a secondcolumn of pixels, each pixel in the first column of pixels being offsetfrom an adjacent pixel in the first column of pixels by a first pixelpitch, the second column of pixels being horizontally offset from thefirst column of pixels by the first pixel pitch, the second column ofpixels being vertically offset from the first column of pixels by afirst vertical pitch; and positioning a set of input channels interposedbetween the first transmitting optic and the pixel array, the set ofinput channels comprising at least a first plurality of input channelsand a second plurality of input channels, each of the first plurality ofinput channels configured to communicate one of collected illuminationbeams from the first transmitting optic to a corresponding pixel in thefirst column of pixels, each of the second plurality of input channelsconfigured to communicate one of the collected illumination beams fromthe first transmitting optic to a corresponding pixel in the secondcolumn of pixels.

An example method of collecting distance information comprises using anoptical system that has a first transmitting optic configured to collectreflected illumination beams of a plurality of illumination sources froma field outside the optical system; a pixel array comprising at least afirst column of pixels and a second column of pixels, each pixel in thefirst column of pixels being offset from an adjacent pixel in the firstcolumn of pixels by a first pixel pitch, the second column of pixelsbeing horizontally offset from the first column of pixels by the firstpixel pitch, the second column of pixels being vertically offset fromthe first column of pixels by a first vertical pitch; and a set of inputchannels interposed between the first transmitting optic and the pixelarray, the set of input channels comprising at least a first pluralityof input channels and a second plurality of input channels, each of thefirst plurality of input channels configured to communicate one ofcollected illumination beams from the first transmitting optic to acorresponding pixel in the first column of pixels, each of the secondplurality of input channels configured to communicate one of thecollected illumination beams from the first transmitting optic to acorresponding pixel in the second column of pixels.

An example method of collecting distance information comprises providingan optical system that has a first transmitting optic configured tocollect reflected illumination beams of a plurality of illuminationsources from a field outside the optical system; a pixel arraycomprising at least a first column of pixels and a second column ofpixels, each pixel in the first column of pixels being offset from anadjacent pixel in the first column of pixels by a first pixel pitch, thesecond column of pixels being horizontally offset from the first columnof pixels by the first pixel pitch, the second column of pixels beingvertically offset from the first column of pixels by a first verticalpitch; and a set of input channels interposed between the firsttransmitting optic and the pixel array, the set of input channelscomprising at least a first plurality of input channels and a secondplurality of input channels, each of the first plurality of inputchannels configured to communicate one of collected illumination beamsfrom the first transmitting optic to a corresponding pixel in the firstcolumn of pixels, each of the second plurality of input channelsconfigured to communicate one of the collected illumination beams fromthe first transmitting optic to a corresponding pixel in the secondcolumn of pixels.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a schematic representation of a system;

FIG. 2 is a schematic representation of one variation of the system;

FIGS. 3A and 3B are graphical representations of one variation of thesystem;

FIG. 4 is a schematic representation of one variation of the system; and

FIGS. 5A1-5A2, 5B1-5B3, 5C1-5C3, and 5D1-5D3 are graphicalrepresentations of one variation of the system.

DESCRIPTION OF THE EMBODIMENTS

The following description of embodiments of the invention is notintended to limit the invention to these embodiments but rather toenable a person skilled in the art to make and use this invention.Variations, configurations, implementations, example implementations,and examples described herein are optional and are not exclusive to thevariations, configurations, implementations, example implementations,and examples they describe. The invention described herein can includeany and all permutations of these variations, configurations,implementations, example implementations, and examples.

1. System

As shown in FIGS. 1 and 2, a system for collecting distance informationwithin a field includes: a bulk receiving optic; a pixel block; a firstset of input channels; and a second set of input channels. The pixelblock includes: a first column of pixels, each pixel in the first columnvertically offset from an adjacent pixel in the first column by a pixelpitch; and a second column of pixels horizontally offset from the firstcolumn by the pixel pitch and vertically offset from the first column bya vertical pitch, each pixel in the second column vertically offset froman adjacent pixel in the second column by the pixel pitch, the verticalpitch comprising a fraction of the pixel pitch. The first set of inputchannels interposed between the bulk receiving optic and the pixelblock, each input channel in the first set of input channels configuredto communicate light incident from the bulk receiving optic to acorresponding pixel in the first column of pixels. The second set ofinput channels horizontally offset from the set of input channels andinterposed between the bulk receiving optic and the pixel block, eachinput channel in the second set of input channels configured tocommunicate light incident from the bulk receiving optic to acorresponding pixel in the second column of pixels.

2. Applications

The system functions as an image sensor that, when rotated about an axisparallel to a column of pixels, collects three-dimensional distance dataof a volume occupied by the system. In particular, during operation, thesystem can collect three-dimensional distance data over each of asequence of scan cycles and can reconstruct these into a virtualthree-dimensional representation of the volume occupied by the system,such as based on recorded times between transmission of an illuminatingbeam from an illumination source and detection of photons at the same orsimilar frequency or temporal patter at each pixel or by implementingphase-based measurement techniques.

The system includes two or more columns of pixels in a skewed grid arraylayout, wherein adjacent columns of pixels are vertically andhorizontally offset such that the set of pixels project onto a singlevertical column of pixels with one pixel per row. The system alsoincludes one input channel per pixel, and the input channels pass lightfrom a common bulk receiving optic to their corresponding pixels. Thesystem can also include an actuator that rotates the pixel block, theinput channels, and the bulk receiving optic about a vertical axis suchthat each pixel (and each corresponding input channel) traverses aunique circular path parallel to and vertically offset from a uniquecircular path traversed by each other pixel in the system during asingle rotation of the rotary actuator (hereinafter a “scan cycle”). Thesystem can collect data from each pixel at each of multiple arcuatesampling positions within one scan cycle and combine these datacollected from multiple columns of pixels into a single vertical columnof distances—to external surfaces within (approximately) a singlevertical plane coincident the axis of rotation of the system—for eacharcuate sampling period within the scan cycle. Therefore, the system canoutput data (e.g., distance values) in a format substantially similar todata output by a similar scanning system including only a single columnof pixels. However, because the system includes multiple vertically- andhorizontally-offset columns of pixels, each pixel in the system candefine a greater height—and therefore include a greater number ofdetectors and exhibit a greater dynamic range—than a pixel in thesimilar scanning system of approximately the same overall height andincluding the same number of pixels at the same effective (vertical)pixel pitch.

The system can output a matrix of range values per scan cycle, whereinall range values in one row of the matrix correspond to outputs of onespecific pixel in the pixel block, and wherein each range value in onerow of the matrix corresponds to an output of the corresponding pixel ata unique angular position of the sensor block within one scan cycle.Because adjacent pixels columns in the system are horizontally andvertically offset from one another, the system populates each row of amatrix for a scan cycle with one range value at a time (i.e., per targetangular sampling position) rather than simultaneously. Horizontal andvertical offset between adjacent columns of pixels also enables eachpixel in the system to span a greater area (and thus include moredetectors) for a given effective vertical pitch of the system, therebyyielding a relatively large ratio of dynamic range to size of theoptical system. Furthermore, though the area of each pixel on the pixelblock spans a relatively large area, each pixel is paired with an inputchannel including an aperture that constrains the field of view of thepixel such that the pixel retains relatively high spatial selectivity.Therefore, the system can include horizontally and vertically offsetcolumns of pixels and corresponding input channels that enable: highdynamic range through large pixel areas; high spatial selectivitythrough small fields of view for each pixel; and high resolution throughsmall effective pixel vertical pitch within a compact system.

3. Pixel

The system includes multiple pixels, and each pixel can include one ormore detectors configured to detect incident light. For example, a pixelcan output a count of incident photons, a time between incident photons,a time of incident photons (e.g., relative to an illumination outputtime), or other relevant data, and the system can transform these datainto distances from the system to external surfaces in the fields ofview of these pixels. By merging these distances with the position ofpixels at which these data originated and relative positions of thesepixels at a time that these data were collected, the system (or otherdevice accessing these data) can reconstruct a three-dimensional(virtual or mathematical) model of a space occupied by the system, suchas in the form of 3D image represented by a rectangular matrix of rangevalues, wherein each range value in the matrix corresponds to a polarcoordinate in 3D space.

Each detector within a pixel can be configured to detect a single photonper sampling period. A pixel can thus include multiple detectors inorder to increase the dynamic range of the pixel; in particular, thedynamic range of the pixel (and therefore of the system) can increase asa number of detectors integrated into each pixel increases, and thenumber of detectors that can be integrated into a pixel can scalelinearly with the area of the pixel. For example, a pixel can include anarray of single-photon avalanche diode detectors (“SPADs”), such as 32detectors on a 6×6 grid array less one detector in each of four corners,as shown in FIG. 4. For detectors ten microns in diameter, the pixel candefine a footprint approximately 400 microns square. However, the systemcan include any other type of pixel including any other number ofdetectors.

4. Pixel Pattern

The system includes a pixel block including: a first column of pixels,each pixel in the first column vertically offset from an adjacent pixelin the first column by a pixel pitch; and a second column of pixelshorizontally offset from the first column by the pixel pitch andvertically offset from the first column by a vertical pitch, each pixelin the second column vertically offset from an adjacent pixel in thesecond column by the pixel pitch, the vertical pitch comprising afraction of the pixel pitch. Generally, the pixel block includesmultiple rows and columns of pixels in a skewed grid array, wherein eachcolumn includes multiple pixels vertically aligned, and wherein each rowcorresponds to a unique vertical distance from the nominal axis of thebulk receiving optic and includes a single pixel, as shown in FIGS. 1,2, and 4. In particular, the pixel block can include multiple columns ofpixels laterally and vertically offset—compared to a single column ofpixels—to enable each pixel to be taller and wider—thereby enabling eachpixel to include a greater number of detectors and increasing thedynamic range of the system—without necessitating a taller pixel blockto accommodate such greater vertical pitch between pixels.

In one implementation, the pixel block and pixels are integrated into asingular integrated circuit. For example, the pixel block and pixels canbe defined in a single application-specific integrated circuit (or“ASIC”). In this example, each input channel can include an aperturethat limits the field of view of a corresponding pixel on the ASIC inorder to achieve greater spatial selectivity for the pixel.

4.1 Pixel Pattern: 32×2:

In one configuration, the system includes two columns of pixels, such asa 32×2 array of pixels and a corresponding 32×2 array of input channelsthat share a common bulk receiving optic. In this configuration, thesystem may exhibit a bulk resolution identical to that of asingle-column system including the same number of pixels arranged on apixel block of approximately the same height at the same effectivevertical pixel pitch, but the two-column system may exhibit greaterdynamic range than the single-column system. In particular, pixels inboth a first column and a second column of the two-column system can beoffset vertically by a second vertical pitch double a first verticalpitch of the single-column system (e.g., 200 microns versus 100microns), and the second column of pixels can be offset vertically fromthe first column of pixels by half of the second virtual pitch, therebyproviding space in the two-column system for pixels twice the height ofpixels in the single-column system given the same number of pixelsarranged on a pixel block of approximately the same height. Therefore,for square pixels, each pixel in the two-column system can define anarea approximately four times that of a pixel in the single-columnsystem, can thus include approximately four times the number ofdetectors as a pixel in the single-column system, and can thus exhibitapproximately four times the dynamic range of a pixel in thesingle-column system. For example, for a pixel block approximately 640microns tall and including 64 pixels (i.e., a 100-micron verticalpitch): the single-column system can include 64 100-micron-squarepixels, each pixel including four 50-micron-wide detectors; and thetwo-column system can include a first column of 32 200-micron-squarepixels and a second column of 32 200-micron-square pixels, each pixelincluding eight 50-micron-wide detectors.

However, because the two-column system includes two columns of pixels,wherein both columns are horizontally offset from a horizontal center ofthe system (i.e., a y-axis of the pixel block), pixels in the firstcolumn can exhibit fields of view angularly offset—in the horizontalplane—from fields of view of pixels in the second column. Thus, thefields of view of pixels in the first column can be offset laterallyfrom fields of view of pixels in the second column by greater amounts atincreasing distances from the system. Horizontal offset between the twocolumns of pixels that share the same bulk receiving optic can thusmanifest as angular offset—in a horizontal plane—between the fields ofview of the first column of pixels and the fields of view of the secondcolumn of pixels (hereinafter “horizontal distortion”).

Furthermore, such horizontal distortion may not be uniform across pixelsin one pixel column. In particular, the field of view of a pixel in thefirst pixel column can be angularly offset from a center (e.g., normal)axis of the bulk lens as a function of distance of the pixel from thecenter axis of the bulk optic such that a pixel at the bottom of thefirst pixel column exhibits a maximum negative angular offset in thehorizontal plane and such that a pixel at the top of the first pixelcolumn exhibits a similar maximum positive angular offset in thehorizontal plane. However, the system can compensate for such variationsin horizontal offset angles (e.g., “yaw” angles) of fields of view ofpixels in each column in a correction matrix, as described below.

4.2 Pixel Pattern: 16×4:

In another configuration shown in FIGS. 1 and 2, the system includesfour columns of pixels, such as a 16×4 array of pixels and acorresponding 16×4 array of input channels that share a common bulkreceiving optic. In this configuration, the system may exhibit a bulkresolution identical to that of one- and two-column systems includingthe same number of pixels arranged on a pixel block of approximately thesame height at the same effective vertical pixel pitch, but thefour-column system may exhibit greater dynamic range than the one- andtwo-column systems. In particular, pixels in each column of thefour-column system can be offset vertically by a fourth vertical pitchhalf the second vertical pitch of the two-column system (e.g., 400microns versus 200 microns), and each column of pixels in thefour-column system can be offset vertically from an adjacent column ofpixels by one-quarter of the fourth virtual pitch, thereby providingspace in the four-column system for pixels twice the height of pixels inthe two-column system given the same number of pixels arranged on apixel block of approximately the same height. Therefore, for squarepixels, each pixel in the four-column system can define an areaapproximately four times that of a pixel in the two-column system, canthus include approximately four times the number of detectors as a pixelin the two-column system, and can thus exhibit approximately four timesthe dynamic range of a pixel in the two-column system. In the exampleabove, for a pixel block approximately 640 microns tall and including 64pixels, the four-column system can include four columns of pixels, eachcolumn including sixteen 400-micron-square pixels, each pixel including32 50-micron-wide detectors.

However, because the four-column system includes four columns of pixels,all horizontally offset from a center of the system, pixels in aleftmost column can exhibit fields of view angularly offset—in thehorizontal plane—from fields of view of pixels in a rightmost columngreater than (e.g., twice) the angular offset—in the horizontalplane—between fields of view of pixels in the first and second columnsof the two-column system described above. The four-column system canthus exhibit greater horizontal distortion than the two-column system,such as shown in FIG. 3A.

4.3 Pixel Pattern: 8×8:

In yet another configuration, the system includes eight columns ofpixels, such as an 8×8 array of pixels and a corresponding 8×8 array ofinput channels that share a common bulk receiving optic. In thisconfiguration, the system may exhibit a bulk resolution identical tothat of one-, two-, and four-column systems including the same number ofpixels arranged on a pixel block of approximately the same height at thesame effective vertical pixel pitch , but the eight-column system mayexhibit greater dynamic range than the one-, two-, and four-columnsystems. In particular, pixels in each column of the eight -columnsystem can be offset vertically by an eight vertical pitch twice thefourth vertical pitch of the four-column system (e.g., 800 micronsversus 400 microns), and each column of pixels in the eight-columnsystem can be offset vertically from an adjacent column of pixels byone-eighth of the eight virtual pitch, thereby providing space in theeight-column system for pixels twice the height of pixels in thefour-column system given the same number of pixels arranged on a pixelblock of approximately the same height. Therefore, for square pixels,each pixel in the eight-column system can define an area approximatelyfour times that of a pixel in the four-column system, can thus includeapproximately four times the number of detectors as a pixel in thefour-column system, and can thus exhibit approximately four times thedynamic range of a pixel in the four-column system. In the exampleabove, for a pixel block approximately 640 microns tall and including 64pixels, the eight-column system can include eight columns of pixels,each column includes eight 800-micron-square pixels, each pixelincluding ˜120 50-micron-wide detectors.

However, because the eight-column system includes eight columns ofpixels, all horizontally offset from a center of the system, pixels in aleftmost column can exhibit fields of view angularly offset—in thehorizontal plane—from fields of view of pixels in a rightmost columntwice the angular offset—in the horizontal plane—between fields of viewof pixels in the leftmost and rightmost columns of the four-columnsystem. The eight-column system can thus exhibit greater horizontaldistortion than the four-column system described above.

However, the system can include any other number of pixels arranged inany other number of columns or rows to achieve at least a thresholdresolution, a minimum dynamic range, a maximum horizontal and/orvertical optical distortion of the fields of views of pixels on theperiphery of the pixel block, or a maximum width and/or height of thepixel block, etc.

5. Bulk Receiving Optic and Input Channels

As shown in FIGS. 1, 3A, and 3B, the system also includes: a bulkreceiving optic; a first set of input channels interposed between thebulk receiving optic and the pixel block, each input channel in thefirst set of input channels configured to communicate light incidentfrom the bulk receiving optic to a corresponding pixel in the firstcolumn of pixels; and a second set of input channels horizontally offsetfrom the set of input channels and interposed between the bulk receivingoptic and the pixel block, each input channel in the second set of inputchannels configured to communicate light incident from the bulkreceiving optic to a corresponding pixel in the second column of pixels.Generally, the bulk receiving optic functions to collect light (i.e.,electromagnetic radiation) from outside the system; and each inputchannel functions to collect light from the bulk receiving optic, tofilter this light, and to pass light over a relatively narrow wavelengthband to a corresponding pixel in the pixel block.

In one implementation, each input channel is coaxial with itscorresponding pixel such that the first and second sets of inputchannels are arranged in a skewed grid array substantially similar tothe skewed grid array defined by the pixels, as described above. Eachinput channel can include: an aperture arranged on the focal plane; afilter configured to pass perpendicular incident light at an operatingfrequency (or within a narrow operating band); an input lens interposedbetween the aperture and the filter and configured to output collimatedlight to the filter; and an output lens adjacent the filter opposite theinput lens and configured to spread light passed by the filter across acorresponding pixel in the pixel block (and/or to re-focus light passedby the filter into the active areas of a corresponding pixel).Generally, the bulk receiving optic, apertures, input lenses, opticalfilter, and the pixels cooperate to collect light (e.g., ambient lightand light output by the illumination source), to collimate this light,to reject all light outside of a narrow band of wavelengths including acenter output wavelength of an illumination source (described below),and to detect light that reached the pixel. The system can thustransform an incident photon count, a time between incident photons, anincident photon time relative to an illumination beam output time, etc.recorded by a particular pixel during one sampling period into adistance from the system to an external surface in a field of view ofthe particular pixel, as defined by a corresponding input channel andthe bulk receiving optic.

In this implementation, the set of input channels can be defined in asingle input block including: an aperture layer arranged behind the bulkreceiving optic and defining one input aperture per input channel; alens layer adjacent the aperture layer opposite the bulk receiving opticand defining an input lens substantially axially aligned with acorresponding input aperture for each input channel; and an opticalfilter adjacent the lens layer opposite the aperture layer and spanningthe lens layer. In this implementation, the bulk receiving optic ischaracterized by a bulk focal distance, is offset from a focal plane bythe bulk focal distance, and functions to project incident light raysfrom outside the system toward the focal plane. For example, the bulkreceiving optic can include multiple lenses, such as one or morebi-convex lenses (shown in FIGS. 1 and 4) and/or plano-convex lenses,that cooperate to form a converging lens characterized by a particularbulk focal length at or near the center wavelength of perpendicularlight rays passed by the optical filter (i.e., a “nominal operatingwavelength of the system”). (The bulk receiving lens can also define anominal axis perpendicular to the focal plane, as referenced below.)

The aperture layer: includes a relatively thin opaque structure arrangedbehind the bulk receiving optic and coincident the focal plane; anddefines one aperture per input channel and a stop region around theapertures. The stop region of the aperture layer rejects (e.g., blocks,absorbs, reflects) incident light rays, and each aperture passesincident light rays toward its corresponding input lens. For example,the aperture layer can define a set of apertures, wherein each apertureis of a diameter approaching a diffraction-limited diameter to maximizegeometrical selectivity of the field of view of the system.

In this implementation, the input lens is characterized by a secondfocal length, is offset from the focal plane by the second focal length,collimates lights rays passed by the aperture, and passes collimatedlight rays to the optical filter. For example, the input block caninclude one input lens per channel, wherein each input lens includes aconverging lens characterized by a ray cone substantially matched to aray cone of the bulk receiving optic and can be offset from the focalplane of the bulk receiving optic by a relatively short second focallength to preserve the aperture of the bulk receiving optic and tocollimate light passed by a corresponding aperture. The optical filterreceives collimated light—in a spectrum of wavelengths—from the inputlens, passes a relatively narrow band of wavelengths of light (e.g., theoperating wavelength +/−0.25 nanometers) to the corresponding pixel, andblocks (e.g., reflects, absorbs) light outside of this narrow wavelengthband. For example, the optical filter can include a narrow opticalbandpass filter.

In one example in which the system includes an illumination source, asdescribed below, the illumination source can output light(predominantly) at a nominal wavelength of 900 nm, and the opticalfilter can define a planar optical bandpass filter configured to passlight (incident on the optical filter at an angle of 90°) between 899.95nm and 900.05 nm and configured to block substantially all light(incident on the optical filter at an angle of 90°) outside of thisband. A pixel in the set of pixels can thus receive light (i.e.,“photons”) passed by the optical filter, detect these incident photons,and output a signal corresponding to a number or rate of detectedphotons during a sampling period.

In this implementation, the bulk receiving optic, the aperture layer,the lens layer, the optical filter, and the output lenses can befabricated and then aligned with and mounted onto the pixel block. Inone example, the optical filter is fabricated by coating a fused silicasubstrate. Photoactive optical polymer is then deposited over theoptical filter, a lens mold defining an array of lens forms placed overthe photoactive optical polymer, and a UV light source activated to curethe photoactive optical polymer into a pattern of lenses across theoptical filter. Standoffs are similarly molded or formed across theoptical filter via photolithography techniques. The aperture layer isseparately fabricated by selectively metallizing a glass wafer andetching apertures into this metallic layer; the glass wafer is thenbonded or otherwise mounted to these standoffs. In this example, theassembly is subsequently inverted, and a second set of standoffs issimilarly fabricated across the optical filter opposite the lens layer.The pixel block (e.g., a discrete image sensor) is aligned with andbonded to the second set of standoffs; the bulk receiving optic issimilarly mounted over the aperture layer to complete the system.

Alternatively, the pixel block can be fabricated on a semiconductorwafer (e.g., in the form of an application-specific integrated circuit),and the bulk receiving optic, the aperture layer, the lens layer, andthe optical filter can be fabricated directly onto the semiconductorwafer—over the pixel block—via photolithography and wafer-level bondingtechniques. However, the bulk receiving optic, the aperture layer, thelens layer, the optical filter, and the pixel block can be fabricatedand assembled in any other way and according to any other method ortechnique.

6. Output Circuit

As shown in FIG. 1, the system can include an output circuit, includinga bulk transmitting optic and an illumination source. In oneimplementation, the bulk transmitting optic: is substantially identicalto the bulk receiving optic in material, geometry (e.g., focal length),optical properties, and/or thermal isolation, etc.; and is adjacent andoffset laterally and/or vertically from the bulk receiving optic.

In one example, the illumination source includes a monolithic VCSELarray of optical emitters arranged behind the bulk transmitting optic.In this example, the illumination source can include a laser diode arraydefining a column of optical emitters characterized by an emitter pitchdistance substantially identical to the aperture pitch distance. In thisexample, each optical emitter can output an illuminating beam of aninitial diameter substantially identical to (or slightly greater than)the diameter of a corresponding aperture in the aperture layer, and theillumination source can be arranged along the focal plane of the bulktransmitting optic such that each illuminating beam projected from thebulk transmitting optic into the field ahead of the system is ofsubstantially the same size and geometry as the field of view of acorresponding input channel—and therefore the field of view of acorresponding pixel—at any distance from the system, as shown in FIG. 4.Therefore, the illumination source and the bulk transmitting optic cancooperate to project substantially illuminating beams into the fields ofview of the input channels with relatively little or no light projectedbeyond these fields of view of the input channels.

In this example, the system can selectively project illuminating beamsinto a field ahead of the system according to an illumination patternthat substantially matches—in size and geometry across a range ofdistances from the system—the fields of view of the input channels(e.g., fields of view defined by the apertures). Therefore, theillumination source can illuminate substantially only surfaces in thefield ahead of the system that are within the fields of view ofcorresponding pixels such that minimal power output by the system viathe illumination source is wasted by illuminating surfaces in the fieldfor which the pixels are blind. Furthermore, the center outputwavelength of the illumination source can be matched to the centerwavelength passed by the filter. The system can thus achieve arelatively high ratio of signal (e.g., photons originating from theillumination source and passed to the pixels on the sensor block) tonoise (e.g., photons not originating from the illumination source, suchas ambient light, and passed to the pixels on the sensor block).

7. Data Acquisition

During operation, the system can collect light data from the set ofpixels and transform these light data into distance values during asingle sampling period. In one implementation, during a sampling period,the system: activates the illumination source of the output circuit inorder to project light into fields of view of each pixel and inputchannel; records a time that the illumination source was activated (an“illumination timestamp”); and reads each detector in each pixel, suchas by storing in memory a number of detectors in each pixel thatrecorded an incident photon since a last sampling period and incidenttimes of these photons and then clearing all detectors in each pixel.During a sampling period, the system can also calculate a distance to asurface in a field of view of a pixel based on a difference between theillumination timestamp and a time of peak frequency of incident photonssince the last sampling period for each pixel in the set. For example,for each pixel, upon conclusion of a sampling period, the system canimplement time of flight techniques to transform an illuminationtimestamp and a time of peak incident photon rate at a pixel between thecurrent and a last sampling period into a distance from the system to anexternal surface within the field of view of the pixel. However, thesystem can implement any other method of technique to illuminate fieldsof view of each pixel and input channel during a sampling period and toprocess data collected from the set of pixels into distance values orrelated values.

The system can further include an actuator configured to rotate thepixel block, input block, and bulk receiving optic during operation. Forexample: the rotary actuator can include a rotary electric motor with anoptical encoder; the pixel block, input block, and bulk receiving opticcan be mounted in-unit on an output shaft of the rotary electric motor;and the system can implement closed-loop feedback controls to maintainthe rotational speed of the rotary electric motor at 60 Hz (or 360 rpm)based on outputs of the optical encoder.

As described below, the system can execute one sampling period at eachof a number of arcuate sampling positions per single rotation of thepixel block. For example, the system can execute 2048 arcuate samplingpositions and output a single nominal matrix containing 2048 columns ofdistance values per each 360° rotation of the pixel block (i.e., scancycle), wherein a single nominal matrix generated during a scan cyclethus represents distances from the system to external surfaces 360°around the sensor (at some viewing angle defined by the bulk receivingoptic and a number of pixels in each column of pixels).

8. Nominal Matrix

Because the system includes multiple columns of pixels, data output bythe set of pixels during a single sampling period corresponds tomultiple columns of distance values, each column corresponding to aunique yaw angle relative to the pixel block. Similarly, because eachpixel in the system is arranged at a unique vertical position (i.e.,because the array of pixels project to a single column ofnon-overlapping pixels), data output by the set of pixels during asingle sampling period corresponds to multiple rows of distance values,wherein each row includes a single distance value and corresponds to aunique pitch angle relative to the pixel block. In particular, thesystem can assemble data collected from the set of pixels during asingle sampling period into multiple incomplete columns of distancevalues, wherein each incomplete column of distance values corresponds toone unique yaw angle.

However, the system can combine distance values generated from datacollected from a second column of pixels during a first sampling periodwith distance values generated from data collected by a first column ofpixels during a second sampling period in order to complete a secondcolumn of distance values, as shown in FIGS. 5A1-5A2. The system canrepeat this process at each arcuate sampling position during a singlerotation of the system (i.e., a single scan cycle) in order to generatea matrix (or other data container) containing one complete column ofdistance values for non-overlapping pitch angles for each arcuatesampling position implemented by the system, as shown in FIGS. 5D1-5D3.

In one example, the system includes a 16×4 array of pixels with avertical offset of Y between adjacent columns of pixels and a pixelpitch of 4Y in each column of pixels, as shown in FIGS. 2 and 4. In thisexample, the system implements 2048 sampling periods per rotation for anangular offset of 0.176° between adjacent arcuate sampling positions. Ata first arcuate sampling position of 0°, the system executes a firstsampling routine, as described above. The system then: populates the[(1,1), (5,1), (9,1), . . . (57,1), and (61,1)] positions within adistance matrix with distance values calculated from data received fromthe first, second, third, fourth, . . . fifteenth, and sixteenth pixelsin the first column, respectively, during the first sampling period;populates the [(2,2), (6,2), (10,2), . . . (58,2), and (62,2)] positionswithin the distance matrix with distance values calculated from datareceived from the first, second, third, fourth, . . . fifteenth, andsixteenth pixels in the second column, respectively; populates the[(3,3), (7,3), (11,3), . . . (59,3), and (63,3)] positions within thedistance matrix with distance values calculated from data received fromthe first, second, third, fourth, . . . fifteenth, and sixteenth pixelsin the third column, respectively; and populates the [(4,4), (8,4),(12,4), . . . (60,4), and (64,4)] positions within the distance matrixwith distance values calculated from data received from the first,second, third, fourth, . . . fifteenth, and sixteenth pixels in thefourth column, respectively, as shown in FIGS. 5A1-5A2.

During the same scan cycle, the rotary actuator rotates the pixel blockto a next arcuate sampling position of 0.176°, and the system thenexecutes a second sampling routine. During the second sampling, thesystem: populates the [(1,2), (5,2), (9,2), . . . (57,2), and (61,2)]positions within the distance matrix with distance values calculatedfrom data received from the first, second, third, fourth, . . .fifteenth, and sixteenth pixels in the first column, respectively,during the second sampling period; populates the [(2,3), (6,3), (10,3),. . . (58,3), and (62,3)] positions within the distance matrix withdistance values calculated from data received from the first, second,third, fourth, . . . fifteenth, and sixteenth pixels in the secondcolumn, respectively; populates the [(3,4), (7,4), (11,4), . . . (59,4),and (63,4)] positions within the distance matrix with distance valuescalculated from data received from the first, second, third, fourth, . .. fifteenth, and sixteenth pixels in the third column, respectively; andpopulates the [(4,5), (8,5), (12,5), . . . (60,5), and (64,5)] positionswithin the distance matrix with distance values calculated from datareceived from the first, second, third, fourth, . . . fifteenth, andsixteenth pixels in the fourth column, respectively, as shown in FIGS.5B1-5B3. The system repeats this process for each subsequent arcuatesampling position of the scan cycle, such as shown in FIGS. 5C1-5C3 and5D1-5D3, in order to form a 2048×64 matrix containing 2048 columns,wherein each column corresponds to a unique yaw angle relative to therotary actuator and contains 64 distance values, wherein each distancevalue in a column corresponds to a unique pitch angle relative to thepixel block, as shown in FIG. 3B.

The system can thus construct one nominal matrix containing a column ofdistance values corresponding to each arcuate sampling position within asingle 360° rotation of the pixel per scan cycle. In particular, thesystem can generate one nominal matrix—per scan cycle—representingdistances of surfaces from the pixel block about a full 360° rotationaxis of the system. For example, the rotary actuator can rotate thesystem at a rate of 360 rpm, and the system can generate one nominalmatrix per 16.7 milliseconds (i.e., at a rate of 60 Hz).

Furthermore, to achieve vertical alignment of the pixel columns at eachsampling position, two adjacent columns of pixels (and two correspondingcolumns of input channels) can be horizontally offset by a horizontalpitch distance corresponding to a focal length of the bulk receivingoptic and an angular pitch between adjacent arcuate sampling positions.In one example, the pixel block includes a 16×4 array of pixels, thebulk receiving optic is characterized by a focal length of 10millimeters, each input channel is coaxial with its corresponding pixel,and the system implements2048 sampling periods per scan cycle (i.e., perrotation). In this example, the angular offset between adjacent arcuatesampling positions is 0.176°, and the horizontal offset between adjacentpixel columns—and adjacent columns of corresponding apertures—is 400microns such that the second column of pixels at a second arcuatesampling position of 0.176° is vertically aligned with a first column ofpixels in a first arcuate sampling position of 0°. During a single scancycle, the system can thus sample all pixels at each of the 2048 arcuatesampling positions to collect 2048 columns of light data in a single360° rotation.

9. Distortion Correction

Because the system contains multiple laterally-offset columns of pixelssharing a common bulk receiving optic, the fields of view of pixels intwo adjacent columns of pixels may not share the same yaw angle relativeto the pixel block, as shown in FIG. 3A. Thus, a column in a nominalmatrix constructed from data collected over a sequence of samplingperiods during a scan cycle can contain a set of distance valuesrepresenting multiple different true yaw angles relative to the pixelblock. For example, for the system described above that includes a 16×4skewed grid array of pixels: pixels in the first column can exhibitfields of view offset −0.03° in yaw from the nominal axis of the bulkreceiving optic; pixels in the second column can exhibit fields of viewoffset −0.01° in yaw from the nominal axis of the bulk receiving optic;pixels in the third column can exhibit fields of view offset +0.01° inyaw from the nominal axis of the bulk receiving optic; and pixels in thefourth column can exhibit fields of view offset +0.03° in yaw from thenominal axis of the bulk receiving optic given a particular operatingtemperature. In this example: a (1,1) distance value in the nominalmatrix can thus represent a distance to a surface in a field of viewangularly offset from the nominal axis of the bulk receiving optic by−0.03° in yaw; a (2,1) distance value in the nominal matrix can thusrepresent a distance to a surface in a field of view angularly offsetfrom the nominal axis of the bulk receiving optic by −0.01° in yaw; . .. a (63,1) distance value in the nominal matrix can thus represent adistance to a surface in a field of view angularly offset from thenominal axis of the bulk receiving optic by +0.01° in yaw; and a (64,1)distance value in the nominal matrix can thus represent a distance to asurface in a field of view angularly offset from the nominal axis of thebulk receiving optic by +0.03° in yaw at the particular operatingtemperature.

Similarly, because pixels in a single column within the system arevertically offset but share a common bulk receiving optic, the fields ofview of two adjacent pixels in one column of pixels may not share thesame pitch angle relative to the pixel block, as shown in FIG. 3B. Thus,a column in a nominal matrix constructed from data collected during ascan cycle can contain a set of distance values representing multipledifferent true yaw pitch angles relative to the pixel block. Forexample, for the system described above that includes a 16×4 skewed gridarray of pixels: a first pixel in the first column can exhibit a fieldof view offset +0.25° in pitch from the nominal axis of the bulkreceiving optic; a second pixel in the first column can exhibit a fieldof view offset +0.22° in pitch from the nominal axis of the bulkreceiving optic; . . . a sixteenth pixel in the first column can exhibita field of view offset −0.25° in pitch from the nominal axis of the bulkreceiving optic; a first pixel in the second column can exhibit a fieldof view offset +0.243° in pitch from the nominal axis of the bulkreceiving optic; a second pixel in the second column can exhibit a fieldof view offset +0.235° in pitch from the nominal axis of the bulkreceiving optic; . . . a sixteenth pixel in the second column canexhibit a field of view offset −0.258° in pitch from the nominal axis ofthe bulk receiving optic; etc. In this example: a (1,1) distance valuein the nominal matrix can thus represent a distance to a surface in afield of view angularly offset from the nominal axis of the bulkreceiving optic by +0.25° in pitch; a (2,1) distance value in thenominal matrix can represent a distance to a surface in a field of viewangularly offset from the nominal axis of the bulk receiving optic by+0.243° in pitch; a (3,1) distance value in the nominal matrix canrepresent a distance to a surface in a field of view angularly offsetfrom the nominal axis of the bulk receiving optic by +0.235° in pitch; a(4,1) distance value in the nominal matrix can represent a distance to asurface in a field of view angularly offset from the nominal axis of thebulk receiving optic by +0.228° in pitch; a (5,1) distance value in thenominal matrix can represent a distance to a surface in a field of viewangularly offset from the nominal axis of the bulk receiving optic by+0.22° in pitch; etc.

The system can thus generate a nominal matrix containing distancevalues—corresponding to data collected by the set of pixels during ascan cycle—representing distances to surfaces in fields of view offsetfrom the nominal axis of the bulk receiving optic in both pitch and yawaxes. In particular, the system can generate a nominal matrix containinga column of distance values representing a single “ideal” yaw angle of0° relative to the sensor block (e.g., similar to fields of view of asingle column of pixels), but the real horizontal offset between columnsof pixels in the system can yield a difference between this ideal yawangle and the actual yaw angle of fields of view of pixels representedin this column of distance values in the nominal matrix; this differencecan manifest as distortion of distance data along the horizontal axis.Similarly, pixels in a single column of pixels can exhibit fields ofview that increase in pitch angle offset from the nominal axis of thebulk receiving optic with increasing distance from the center of thegrid array of pixels, which can manifest as a lowest resolution at thefirst and last rows and as a greatest resolution at the center row(s) inthe nominal matrix.

The system can thus pair a nominal matrix with a correction matrixdefining pitch and yaw offset angles for each entry in the nominalmatrix. In particular, by merging distance values contained in a nominalmatrix output in a scan cycle with corresponding angular valuescontained in a correction matrix, the system (or other device) cancalculate positions of surfaces detected during the scan cycle to animproved degree of accuracy. For example, for pixels in the first columnof pixels that exhibit fields of view offset −0.03° in yaw from thenominal axis of the bulk receiving optic, the correction matrix candefine a five-centimeter leftward correction of a (1,1) distance valueof 100 meters in the nominal matrix (e.g., 100 meters×sin(−0.03°)=5.2centimeters).

Furthermore, pitch and yaw offset angles of a field of a view of eachpixel in the system can vary with (i.e., be a function of) the focallength of the bulk receiving optic, and the focal length of the bulkreceiving optic can vary with temperature of the system. Therefore, thesystem can pair the nominal matrix with a correction matrix based on atemperature of the system, such as for a bulk receiving optic includingone or more polymer lenses. In one implementation, the system stores aset of preset correction matrices, wherein each correction matrixcorresponds to a particular temperature and contains pitch and yawoffset angles for the field of view of each pixel in the system at theparticular temperature. In this implementation, the system: can alsoinclude a temperature sensor thermally coupled to the bulk receivingoptic; can sample the temperature sensor during operation (e.g., onceper scan cycle); and can pair a nominal matrix generated from datacollected during a scan cycle with a correction matrix—selected from theset of correction matrices—corresponding to a temperature nearest atemperature of the bulk receiving optic recorded during the same scancycle. For example, for the system that operates within a temperaturerange from 119° F. to 121° F., the system can contain 21 presetcorrection matrices, each correction matrix corresponding to one of210.1° F. temperature steps between 119° F. and 121° F., inclusive. Forexample, each correction matrix can be generated empirically bycharacterizing the fields of view of pixels within the system at selectoperating temperatures.

Alternatively, the system can implement a parametric model or otherparametric function to generate a correction matrix based on thetemperature of the bulk receiving optic (or other element within thesystem). However, the system can implement any other method or techniqueto pair a nominal matrix generated from data collected during a scancycle with a correction matrix representing horizontal and verticaldistortion of data contained within the nominal matrix.

10. Increased Resolution

In one variation, the system increases a number of angular samplingexecuted positions per rotation in order to increase the resolution of anominal matrix generated during a scan cycle. In one implementation, thesystem includes a skewed grid array of pixels, wherein adjacent columnsof pixels (and corresponding columns of input channels) are offsetlaterally by a distance corresponding to X-number of radial steps in asingle rotation (e.g., 2048 steps at 0.176° between steps) but executes2X equidistant arcuate sampling positions per complete rotation (e.g.,4096 arcuate sampling positions at 0.088° between steps per scan cycle).

In the example described above in which the system includes a 16×4 arrayof pixels, the system executes a first sampling routine at a firstarcuate sampling position of 0° and then: populates the [(1,1), (5,1),(9,1), . . . (57,1), and (61,1)] positions within a first column in adistance matrix with distance values calculated from data received fromthe first, second, third, fourth, . . . fifteenth, and sixteenth pixelsin the first column of pixels, respectively, during the first samplingperiod; populates the [(2,3), (6,3), (10,3), . . . (58,3), and (62,3)]positions within the third column of the distance matrix with distancevalues calculated from data received from the first, second, third,fourth, . . . fifteenth, and sixteenth pixels in the second column ofpixels, respectively; populates the [(3,5), (7,5), (11,5), . . . (59,5),and (63,5)] positions within the fifth column of the distance matrixwith distance values calculated from data received from the first,second, third, fourth, . . . fifteenth, and sixteenth pixels in thethird column of pixels, respectively; and populates the [(4,7), (8,7),(12,7), . . . (60,7), and (64,7)] positions within the seventh column ofthe distance matrix with distance values calculated from data receivedfrom the first, second, third, fourth, . . . fifteenth, and sixteenthpixels in the fourth column of pixels, respectively.

In this example, the rotary actuator rotates the pixel block, and thesystem executes a second sampling routine once the pixel block reaches anext arcuate sampling position of 0.088°. The system then: populates the[(1,2), (5,2), (9,2), . . . (57,2), and (61,2)] positions within asecond column in the distance matrix with distance values calculatedfrom data received from the first, second, third, fourth, . . .fifteenth, and sixteenth pixels in the first column of pixels,respectively, during the first sampling period; populates the [(2,4),(6,4), (10,4), . . . (58,4), and (62,4)] positions within the fourthcolumn of the distance matrix with distance values calculated from datareceived from the first, second, third, fourth, . . . fifteenth, andsixteenth pixels in the second column of pixels, respectively; populatesthe [(3,6), (7,6), (11,6), . . . (59,6), and (63,6)] positions withinthe sixth column of the distance matrix with distance values calculatedfrom data received from the first, second, third, fourth, . . .fifteenth, and sixteenth pixels in the third column of pixels,respectively; and populates the [(4,8), (8,8), (12,8), . . . (60,8), and(64,8)] positions within the eight column of the distance matrix withdistance values calculated from data received from the first, second,third, fourth, . . . fifteenth, and sixteenth pixels in the fourthcolumn, respectively.

The system repeats this process once upon reaching a third arcuatesampling position at 0.176°, then at a fourth arcuate sampling positionof 0.264° , and for each subsequent arcuate sampling position in a fullrotation of the pixel block in order to form a 4096×64 matrix containing4096 columns, wherein each column corresponds to a unique yaw anglerelative to the rotary actuator and contains 64 distance values, whereineach distance value in a column corresponds to a unique pitch anglerelative to the pixel block.

However, the system can execute a sampling period at any other number ofarcuate sampling positions during a complete rotation of the pixel block(e.g., during a compete scan cycle), and the system can implement anyother method or technique to transform data collected from the set ofpixels during a scan cycle into a nominal matrix of distances from thesystem to external surfaces nearby.

The systems and methods described herein can be embodied and/orimplemented at least in part as a machine configured to receive acomputer-readable medium storing computer-readable instructions. Theinstructions can be executed by computer-executable componentsintegrated with the application, applet, host, server, network, website,communication service, communication interface,hardware/firmware/software elements of a user computer or mobile device,wristband, smartphone, or any suitable combination thereof. Othersystems and methods of the embodiment can be embodied and/or implementedat least in part as a machine configured to receive a computer-readablemedium storing computer-readable instructions. The instructions can beexecuted by computer-executable components integrated bycomputer-executable components integrated with apparatuses and networksof the type described above. The computer-readable medium can be storedon any suitable computer readable media such as RAMs, ROMs, flashmemory, EEPROMs, optical devices (CD or DVD), hard drives, floppydrives, or any suitable device. The computer-executable component can bea processor but any suitable dedicated hardware device can(alternatively or additionally) execute the instructions.

As a person skilled in the art will recognize from the previous detaileddescription and from the figures and claims, modifications and changescan be made to the embodiments of the invention without departing fromthe scope of this invention as defined in the following claims.

What is claimed is:
 1. An optical system for performing distancemeasurements, the optical system comprising: an optical imaging receivemodule comprising a bulk receiver optic, an aperture layer including aplurality of apertures, a lens layer including a plurality of lenses,and a pixel block including a plurality of pixels, wherein the aperturelayer, lens layer and pixel block are arranged to form a plurality ofinput channels with each input channel in the plurality of inputchannels including an aperture from the plurality of apertures, a lensfrom the plurality of lenses and a pixel from the plurality of pixelsand being configured to communicate light incident from the bulkreceiving optic to the pixel of the input channel; an optical imagingtransmit module comprising a bulk transmitter optic and an illuminationsource comprising a plurality of lasers, each laser in the plurality oflasers configured to project a discrete illuminating beam at anoperating wavelength through the bulk transmitter optic; a rotaryactuator comprising a rotary electric motor operatively coupled torotate the plurality of input channels and the bulk receiver optic abouta full 360 degree rotation axis of the system.
 2. The optical system ofclaim 1 wherein the rotary actuator further comprises an optical encoderand wherein the system further comprises circuitry coupled to the rotaryactuator to control a rotational speed of the rotary electric motorbased on outputs of the optical encoder.
 3. The optical system of claim1 wherein the optical system is configured to execute a plurality ofsampling periods during each rotation of the rotary actuator in whichthe optical imaging transmit module activates the illumination source toproject light through the bulk transmitter optic into fields of view ofthe input channels, where each sampling period in the plurality ofsampling periods is taken at a different arcuate sampling position. 4.The optical system of claim 3 wherein the system is configured to,during operation, collect three-dimensional distance data over each of asequence of scan cycles that can be reconstructed into a virtualthree-dimensional representation of a volume occupied by the system. 5.The optical system of claim 4 further comprising an optical filterbetween the aperture layer and the pixel block, the optical filterconfigured to receive light from the plurality of lenses and pass anarrow band of radiation that includes the operating wavelength of theplurality of lasers to the plurality of pixels while blocking radiationoutside the band.
 6. The optical system of claim 5 wherein the pluralityof pixels in the pixel block are arranged in a two-dimensional array. 7.The optical system of claim 6 wherein the two-dimensional array includesa plurality of columns of pixels with each pixel in a given column beingoffset from an adjacent pixel in the given column by a first pixel pitchand wherein each column of pixels is horizontally offset from anadjacent column of pixels by the first pixel pitch and vertically offsetfrom the adjacent column by a second pixel pitch.
 8. The optical systemof claim 7 wherein the rotary actuator is configured to rotate theoptical imaging receive module about a vertical axis such that eachpixel and corresponding input channel traverses a unique circular pathparallel to and vertically offset from a unique circular path traversedby the other pixels and corresponding input channels during a singlerotation of the rotary actuator.
 9. The optical system of claim 5wherein the bulk receiver optic is characterized by a focal planeopposite the field, the aperture layer is coincident the focal plane,each lens in the plurality of lenses is collimating lens characterizedby a lens focal length and offset from the focal plane of the bulkreceiver optic by the lens focal length.
 10. The optical system of claim1 wherein each of the lasers in the plurality of lasers comprises avertical-cavity surface-emitting laser (VCSEL) and each of the pluralityof pixels comprises a plurality of single-photon avalanche diode (SPAD)detectors configured to receive light from a corresponding one of theplurality of lasers.
 11. The optical system of claim 10 wherein eachVCSEL laser outputs an illuminating beam of an initial diameter that issubstantially identical to or slightly greater than a diameter of acorresponding aperture in the aperture layer.
 12. The optical system ofclaim 1 wherein the aperture layer comprises a thin opaque structurearranged along a focal plane of the bulk receiver optic and eachaperture in the plurality of apertures constrains the field of view ofits corresponding pixel such that the pixel retains relatively highspatial selectivity.
 13. The optical system of claim 1 wherein theillumination source is arranged along a focal plane of the bulktransmitting optic such that each illuminating beam projected from thebulk transmitting optic into the field ahead of the system issubstantially the same size and geometry as the field of view of acorresponding input channel at any distance from the system.
 14. Theoptical system of claim 1 wherein the optical imaging transmit modulecan selectively project illuminating beams into a field ahead of thesystem according to an illumination pattern that substantially matches,in size and geometry across a range of distances from the system, thefields of view of the input channels.
 15. The optical system of claim 1wherein the bulk transmitter optic is adjacent to and laterally offsetfrom the bulk receiver optic.
 16. An optical system for performingdistance measurements, the optical system comprising: a laser arrayincluding a plurality of lasers, each laser in the plurality of lasershaving an operating wavelength and configured to project a discreteilluminating beam in a field ahead of the optical system; a pixel blockincluding a plurality of pixels; a bulk receiver optic configured toreceive light from the field; an optical assembly defining a pluralityof input channels disposed between the bulk receiver optic and the pixelblock, each input channel in the plurality of input channels configuredto communicate light from the bulk receiver optic to a pixel in theplurality of pixels, wherein the optical assembly comprises: an aperturelayer arranged behind and coincident with a focal plane of the bulkreceiver optic and defining a plurality of apertures including oneaperture per input channel; a lens layer adjacent the aperture layeropposite the bulk receiver optic, the lens layer comprising a pluralityof lenses including an input lens substantially axially aligned with acorresponding aperture for each input channel; and an optical filterbetween the lens layer and the pixel block and configured to receivelight from the plurality of lenses and pass a narrow band of radiationthat includes the operating wavelength of the plurality of lasers to theplurality of pixels while blocking radiation outside the band; and arotary actuator comprising a rotary electric motor operatively coupledto rotate the plurality of input channels and the bulk receiver opticabout a full 360 degree rotation axis of the system.
 17. The opticalsystem of claim 16 wherein each input channel includes a pixel having afield of view configured to receive light from a corresponding one ofthe plurality of lasers and wherein the laser array can selectivelyproject illuminating beams into the field ahead of the system accordingto an illumination pattern that substantially matches, in size andgeometry across a range of distances from the system, the fields of viewof the input channels.
 18. The optical system of claim 17 wherein therotary actuator further comprises an optical encoder and wherein thesystem further comprises circuitry coupled to the rotary actuator tocontrol a rotational speed of the rotary electric motor based on outputsof the optical encoder.
 19. The optical system of claim 17 wherein theoptical system is configured to execute a plurality of sampling periodsduring each rotation of the rotary actuator in which the plurality oflasers are activated to project light away from the optical system intofields of view of the input channels, where each sampling period in theplurality of sampling periods is taken at a different arcuate samplingposition.
 20. The optical system of claim 17 wherein the aperture layercomprises a thin opaque structure arranged along a focal plane of thebulk receiver optic and each aperture constrains the field of view ofits corresponding pixel such that the pixel retains relatively highspatial selectivity.
 21. The optical system of claim 17 wherein eachlaser in the plurality of lasers comprises a vertical-cavitysurface-emitting laser (VCSEL) and each pixel in the plurality of pixelscomprises a plurality of single-photon avalanche diodes (SPADs).
 22. Anoptical system for performing distance measurements, the optical systemcomprising: a bulk transmitter optic; a monolithic laser array includinga plurality of vertical-cavity surface-emitting lasers (VCSELs) on asingle semiconductor die, wherein each laser in the monolithic laserarray is configured to project a discrete beam through the bulktransmitter optic at an operating wavelength into a field ahead of theoptical system; a pixel block including a plurality of pixels, eachpixel in the plurality of pixels comprising a plurality of single-photonavalanche diode (SPAD) detectors; a bulk receiver optic configured toreceive light rays emitted by the laser array and reflected fromsurfaces; an optical assembly defining a plurality of input channelsdisposed between the bulk receiver optic and the pixel block, each inputchannel in the plurality of input channels configured to communicatelight from the bulk receiver optic to a pixel in the plurality ofpixels, wherein the optical assembly comprises: an aperture layerarranged behind and coincident with a focal plane of the bulk receiveroptic, the aperture layer defining a plurality of discrete apertures ofsubstantially uniform diameter including one aperture per input channeland where adjacent apertures in the plurality of discrete apertures areoffset by a pitch distance that is greater than the diameter of eachaperture in the plurality of discrete apertures; a lens layer adjacentthe aperture layer opposite the bulk receiver optic, the lens layercomprising a plurality of lenses including an input lens substantiallyaxially aligned with a corresponding aperture for each input channel;and an optical filter between the lens layer and the pixel block, theoptical filter configured to receive light from the plurality of lensesand pass a narrow band of radiation that includes the operatingwavelength of the plurality of lasers to the plurality of pixels whileblocking radiation outside the band; and a rotary actuator comprising arotary electric motor operatively coupled to rotate the plurality ofinput channels and the bulk receiver optic about a full 360 degreerotation axis of the system.
 23. The optical system of claim 22 whereinthe aperture layer comprises a thin opaque structure and each aperturein the plurality of apertures constrains the field of view of itscorresponding pixel such that the pixel retains relatively high spatialselectivity.
 24. The optical system of claim 22 wherein the opticalsystem is configured to execute a plurality of sampling periods duringeach rotation of the rotary actuator where each sampling period in theplurality of sampling periods is taken at a different arcuate samplingposition and wherein the signal processing circuit is configured tocount incident photons for the plurality of pixels within each samplingperiod.
 25. The optical system of claim 24 wherein the monolithic laserarray is two-dimensional, wherein the pixel block is arranged in a twodimensional array, and wherein the optical system further comprises asignal processing circuit connected to the pixel block and configured toreconstruct a three-dimensional representation of a field ahead of theoptical system using positions of the pixels and the lasers in the twodimensional arrays.
 26. The optical system of claim 22 wherein theplurality of pixels in the pixel block are arranged in a two-dimensionalarray that includes a plurality of columns of pixels with each pixel ina given column being offset from an adjacent pixel in the given columnby a first pixel pitch and wherein each column of pixels is horizontallyoffset from an adjacent column of pixels by the first pixel pitch andvertically offset from the adjacent column by a second pixel pitch. 27.The optical system of claim 22 wherein the plurality of lasers arearranged along a focal plane of the bulk transmitting optic and areconfigured to selectively project illuminating beams into a field aheadof the system according to an illumination pattern that substantiallymatches, in size and geometry across a range of distances from thesystem, the fields of view of the input channels, wherein eachilluminating beam projected from the bulk transmitting optic into thefield ahead of the system is substantially the same size and geometry ofthe field of view of a corresponding input channel at any distance fromthe system.